Acidity and nucleophilic reactivity of glutathione persulfide

Dayana Benchoam,Jonathan A Semelak,Ernesto Cuevasanta,Mauricio Mastrogiovanni,Juan S Grassano,Gerardo Ferrer-Sueta,Ari Zeida,Madia Trujillo,Matías N Möller,Darío A Estrin,Beatriz Alvarez

doi:10.1074/jbc.ra120.014728

Abstract

Persulfides (RSSH/RSS-) participate in sulfur trafficking and metabolic processes, and are proposed to mediate the signaling effects of hydrogen sulfide (H2S). Despite their growing relevance, their chemical properties are poorly understood. Herein, we studied experimentally and computationally the formation, acidity, and nucleophilicity of glutathione persulfide (GSSH/GSS-), the derivative of the abundant cellular thiol glutathione (GSH). We characterized the kinetics and equilibrium of GSSH formation from glutathione disulfide and H2S. A pKa of 5.45 for GSSH was determined, which is 3.49 units below that of GSH. The reactions of GSSH with the physiologically relevant electrophiles peroxynitrite and hydrogen peroxide, and with the probe monobromobimane, were studied and compared with those of thiols. These reactions occurred through SN2 mechanisms. At neutral pH, GSSH reacted faster than GSH because of increased availability of the anion and, depending on the electrophile, increased reactivity. In addition, GSS- presented higher nucleophilicity with respect to a thiolate with similar basicity. This can be interpreted in terms of the so-called α effect, i.e. the increased reactivity of a nucleophile when the atom adjacent to the nucleophilic atom has high electron density. The magnitude of the α effect correlated with the Brønsted nucleophilic factor, βnuc, for the reactions with thiolates and with the ability of the leaving group. Our study constitutes the first determination of the pKa of a biological persulfide and the first examination of the α effect in sulfur nucleophiles, and sheds light on the chemical basis of the biological properties of persulfides.

Highlights

Persulfides (RSSH/RSS2)7 can be formed in biological systems through several pathways, some of which are dependent on hydrogen sulfide (H2S/HS2)8
A peak with a retention time of 7.7 min was ascribed to GSSH derivatized with mBrB (GSS-B) because it disappeared in the presence of the reductant tris(2-carboxyethyl)phosphine (TCEP), and when more mBrB was added, GSH derivatized with mBrB (GS-B) and H2S derivatized with mBrB (B-S-B) increased
The identities of the four species were confirmed by electrospray ionization MS and MS/MS; the results for GS-B and GSS-B were consistent with a mass increase of 32 Da for the latter (Fig. 1C)

Summary

Introduction

Persulfides (RSSH/RSS2) can be formed in biological systems through several pathways, some of which are dependent on hydrogen sulfide (H2S/HS2). Persulfides can be formed in vivo via reactions of H2S with oxidized thiol derivatives, i.e. disulfides (RSSR9) or sulfenic acids (RSOH) [3], via reactions of thiolates with oxidized sulfur derivatives, e.g. polysulfides Rhodanese can catalyze the reversible reaction between GSSH and sulfite to form GSH and thiosulfate [10, 12, 15]. These processes suggest that GSSH plays key roles in vivo; concentrations of ;35 pmol/mg protein (;7 mM) in mouse liver tissue have been recently reported [16]. If the inner sulfur is attacked, H2S is released and a mixed disulfide is formed

Methods

Results

Conclusion